Container transport apparatus and system

ABSTRACT

A container transport system is provided that may comprise a support surface for supporting one or more stackable beverage containers; at least one aperture sized to accept a portion of one or more stackable beverage containers; a handle attached to the support surface for transporting the container transport apparatus system; and beverage containers attached to the container transport apparatus in a stacked configuration through the at least one aperture.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority to U.S. Provisional Patent Application Ser. No. 62/946,978 entitled “Container Transport Apparatus and Methods Thereof,” filed Dec. 12, 2019, the disclosure of which is incorporated herein by reference in its entirety.

BACKGROUND

Embodiments of the present disclosure generally relate to a container transport apparatus and system for stackable and/or nestable beverage containers and methods thereof. More specifically, embodiments of the present disclosure relate to a container transport apparatus and system for transporting connected stackable and/or nestable beverage containers via a support surface having a handle, or the like.

Beverage containers (e.g., a can of a carbonated beverage, as shown in FIG. 1) are sometimes available for purchase either individually, in a small pack of four or six, in a larger pack of twelve, eighteen or twenty-four or even “economy” packs of thirty, thirty-six or more. Usually such packaging comes in the form of plastic wrapping the containers together, or in the case of larger packs or economy packs, the containers are arranged on a cardboard tray, and subsequently wrapped in a plastic film. When containers or cans are packaged in groups of six, six pack rings are typically used. Six pack rings are a set of connected plastic rings that are used to hold the containers together. The environmental concerns of using these plastic six pack rings, including dangers to marine wildlife, are well-known. Marine wildlife entangled in the rings may face disabling or life-threatening injuries. Furthermore, packaging methods that require the use of a plastic film or wrap may be hazardous to the environment when disposed of and may generally be cost-dependent on oil. Apart from initially binding the containers together for packaging purposes, the plastic film serves no other purpose than added cost and waste.

From usability perspective, when the containers are packaged in bulk with a plastic wrap one problem is that once the package is open the remaining containers are not easy to carry around without falling over or falling out of the package. This creates the possibly of spilling the contents of the containers should they fall and hit the ground during transport. That is, once the integrity of the plastic wrap is broken, the force keeping the containers in place is disrupted. In addition, if one of the containers is emptied, it is not convenient to merely place the empty container back in the original packaging. Rather, a user would need to either dispose of the empty container immediately or carry it around until disposal is convenient. When the user is in an inconvenient location such as the beach, that may not always be easy.

FIG. 1 depicts a can as known in the prior art. A can generally comprises a substantially cylindrical body, having a sidewall 10, a bottom portion 44, and a top 20. The top 20 generally comprises a single opening 40 into the voluminous body of the can, which may be sealed by any number of known sealing means. A form of sealing means is the stay tab or pull tab 30, the operation of which is described in detail in U.S. Pat. No. 3,967,752 (hereinafter, “the '752 patent”). The pull tab 30 works in conjunction with a surface 42 that is semi-weakened, in that it seals the can when undisturbed; however, upon lifting of the pull tab 30, the surface 42 pivots about a point or edge along the opening 40. As described in the '752 patent, one key feature of the pull tab 30 opening means is that both the pull tab 30 and the surface 42 remain connected to the top 20 of the soda can in an open position.

SUMMARY

Embodiments of the present disclosure generally relate to a container transport apparatus and system for stackable and/or nestable beverage containers and methods thereof. More specifically, embodiments of the present disclosure relate to a container transport apparatus and system for transporting connected stackable and/or nestable beverage containers via a support surface having a handle, or the like.

In embodiments of the present disclosure, a container transport system may comprise a container transport apparatus, the container transport apparatus comprising: a support surface for supporting one or more stackable and/or nestable beverage containers; at least one aperture sized to accept a portion of one or more stackable and/or nestable beverage containers; and a handle attached to the support surface for allowing a user to pick up and transport the container transport apparatus system.

BRIEF DESCRIPTION OF THE DRAWINGS

So the manner in which the above recited features of the present disclosure can be understood in detail, a more particular description of embodiments of the present disclosure, briefly summarized above, may be had by reference to embodiments, which are illustrated in the appended drawings. It is to be noted, however, the appended drawings illustrate only typical embodiments of embodiments encompassed within the scope of the present disclosure, and, therefore, are not to be considered limiting, for the present disclosure may admit to other equally effective embodiments, wherein:

FIG. 1 depicts a can as known in the prior art;

FIG. 2 depicts a side view of a nestable beverage container in accordance with embodiments of the present disclosure;

FIG. 3 depicts a cross-sectional view of the nestable beverage container of FIG. 2;

FIG. 4A depicts a top view of the nestable beverage container of FIG. 2;

FIG. 4B depicts a bottom view of the nestable beverage container of FIG. 2;

FIG. 5 depicts a system of nested beverage containers in accordance with embodiments of the present disclosure;

FIG. 6 depicts a side view of a nestable beverage container in accordance with embodiments of the present disclosure;

FIG. 7 depicts a system of nested beverage containers in accordance with embodiments of the present disclosure;

FIG. 8 depicts a carrier for packaging a system of nested beverage containers in accordance with embodiments of the present disclosure;

FIG. 9 depicts a tray for packaging a system of nested beverage containers in accordance with embodiments of the present disclosure;

FIG. 10 depicts a side view of a system of nestable beverage containers in accordance with embodiments of the present disclosure;

FIG. 11 depicts a cross-sectional view of a nestable beverage container in accordance with embodiments of the present disclosure;

FIG. 12 depicts a side view of nestable beverage containers in accordance with embodiments of the present disclosure;

FIG. 13 depicts a side view of nestable beverage containers in accordance with embodiments of the present disclosure;

FIG. 14 depicts a side view of nestable beverage containers in accordance with embodiments of the present disclosure;

FIG. 15 depicts a side view of nestable beverage containers in accordance with embodiments of the present disclosure;

FIG. 16 depicts a top perspective view of a nestable beverage container in accordance with embodiments of the present disclosure;

FIG. 17 depicts a bottom perspective view of a nestable beverage container in accordance with embodiments of the present disclosure;

FIG. 18 depicts a top perspective view of a nestable beverage container in accordance with embodiments of the present disclosure;

FIG. 19 depicts a bottom perspective view of a nestable beverage container in accordance with embodiments of the present disclosure;

FIG. 20 depicts a side view of a container transport apparatus in accordance with embodiments of the present disclosure;

FIG. 21 depicts a top view of a container transport apparatus with nestable beverage containers in accordance with embodiments of the present disclosure;

FIG. 22 depicts a side view of a container transport apparatus with nestable cans and a stand in accordance with embodiments of the present disclosure;

FIG. 23 depicts a side view of a container transport apparatus with a portion having a triangular shape in accordance with embodiments of the present disclosure;

FIG. 24 depicts a side view of a container transport apparatus with a portion having a trapezoidal shape in accordance with embodiments of the present disclosure;

FIG. 25 depicts a side view of a container transport apparatus with a portion having perforated openings in accordance with embodiments of the present disclosure;

FIG. 26 depicts a side view of a container transport apparatus with a portion having indented borders in accordance with embodiments of the present disclosure;

FIG. 27 depicts a front view of a container transport apparatus having three openings for supporting beverage containers in accordance with embodiments of the present disclosure;

FIG. 28 depicts a side view of a container transport apparatus having a central handle for supporting beverage containers in accordance with embodiments of the present disclosure;

FIG. 29 depicts a top view of a container transport apparatus having a central handle for supporting beverage containers in accordance with embodiments of the present disclosure;

FIG. 30 depicts a view of a container transport apparatus in a flattened configuration in accordance with embodiments of the present disclosure;

FIG. 31 depicts a front view of a container transport apparatus in a folded configuration in accordance with embodiments of the present disclosure;

FIG. 32 depicts a top view of a container transport apparatus in a flattened configuration in accordance with embodiments of the present disclosure;

FIG. 33 depicts a front view of a container transport apparatus in a folded configuration in accordance with embodiments of the present disclosure; and

FIG. 34 depicts a front view of a container transport apparatus and beverage containers in accordance with embodiments of the present disclosure;

FIG. 35 depicts a front view of a container transport apparatus and beverage containers in accordance with embodiments of the present disclosure;

FIG. 36 depicts a front view of a container transport apparatus and beverage containers in accordance with embodiments of the present disclosure;

FIG. 37 depicts a perspective left side view of a container transport apparatus and beverage containers in accordance with embodiments of the present disclosure; and

FIG. 38 depicts a perspective right side view of a container transport apparatus and beverage containers in accordance with embodiments of the present disclosure.

The headings used herein are for organizational purposes only and are not meant to be used to limit the scope of the description or the claims. As used throughout this application, the word “may” is used in a permissive sense (i.e., meaning having the potential to), rather than the mandatory sense (i.e., meaning must). Similarly, the words “include”, “including”, and “includes” mean including but not limited to. To facilitate understanding, like reference numerals have been used, where possible, to designate like elements common to the figures.

DETAILED DESCRIPTION

Embodiments of the present disclosure generally relate to a container transport apparatus and system for stackable and/or nestable beverage containers and methods thereof. More specifically, embodiments of the present disclosure relate to a container transport apparatus and system for transporting connected stackable and/or nestable beverage containers, or the like. As used herein, the term “stackable” and “nestable” may be used interchangeably at times and may refer to beverage containers that are attachable and stackable in a vertical configuration, wherein the top of one beverage container is attachable to the bottom of another beverage container.

FIG. 2 depicts a side view of a nestable beverage container in accordance with embodiments of the present disclosure, and FIGS. 3, 4A and 4B depict cross-sectional, top and bottom views of the nestable beverage container depicted in FIG. 2, respectively. A nestable beverage container 100 generally comprises a top portion 110, a bottom portion 120 and a voluminous body 130. The voluminous body 130 is generally defined by the top portion 110, the bottom portion 120 and a side wall 132.

The nestable beverage container 100 may comprise any materials suitable for embodiments of the present disclosure. In embodiments, the nestable beverage container 100 comprises at least one of a polymer, a metal, a metal alloy, glass, combinations thereof or the like.

The top portion 110 generally comprises an opening 112 into the voluminous body 130. In accordance with many embodiments of the present disclosure, the opening 112 is the only means for accessing an interior of the voluminous body 130 and any contents of the nestable beverage container 110.

Generally, the top portion 110 also comprises a sealing means 114. The sealing means 114 may comprise any structure suitable to control access to an interior of the voluminous body 130. In embodiments, the sealing means 114 comprises a threaded surface and an inversely threaded cap for removably sealing the opening 112 of the nestable beverage container 100. In another embodiment, the sealing means 114 comprises a tab and semi-weakened surface covering the opening 112, for example, as found on a typical soda can as shown in FIG. 1. In further embodiments, the sealing means 114 may comprise a peelable tab, wherein the peelable tab is removably affixed over the opening 112 by an adhesive or similar type of cohesion agent. Such type of peelable tabs are commonly utilized as security or tampering devices on various food and beverage products.

In yet another embodiment, the sealing means 114 may comprise a snap-locking cap about a correlating annular tab surrounding the opening 112. In yet further embodiments, the sealing means 114 may comprise a closeable cap, for example, as found on sports drinks, whereby the concept of a threaded cap and surface combination is further complimented by a controllable opening in the cap itself. In such embodiments, the closeable cap may also comprise a dust cap, protecting the portion of the cap from undesirable contaminants.

In many embodiments of the present disclosure, the top portion 110 further comprises a connection means 116 for allowing the nestable beverage container 100 to be nested within an adjacent nestable beverage container. In embodiments, the connection means comprises a threaded surface on an exterior of the nestable beverage container. In many of such embodiments, the threaded surface may extend down from a position just beneath the sealing means 114. In another embodiment, the connection means 116 may comprise a threaded surface on the exterior surface of the sealing means 114. For example, where the sealing means 114 comprises a threaded cap as described above, the connection means 116 may comprise a threaded surface on the exterior of the threaded cap. In yet further embodiments, the connection means 116 may comprise an annular projection from the exterior surface of the nestable beverage container 100, for engaging a snap-fit type structure in an adjacent nestable beverage container.

In another embodiment of the present disclosure, the connection means may comprise an annular ring having at least one tab projecting outward from the nestable beverage container. In such an embodiment, the at least one tab may be adapted to fit within an inverse receptive pattern with an adjacent nestable beverage container. Generally, when the tab is inserted into the receptive pattern on the adjacent nestable beverage container, with a short rotation (e.g., quarter turn, half turn, etc.) the tab may be positioned securely within the receptive pattern on the adjacent nestable beverage container. Generally, a plurality of tabs are provided in such types of embodiments.

In yet further embodiments of the present disclosure, the connection means 116 may comprise a specific structural design (e.g., tapering neck, hour-glass shape, etc.) of the outer surface of the top portion 110 to create a friction-type fit with an adjacent nestable beverage container.

The bottom portion 120 may generally comprise a receiving means 122 shaped to conform to the connection means 116 of an adjacently nested beverage container. In many embodiments, the receiving means 122 is substantially an inverse structure of the connection means 116, as positioned on the top portion 110. For example, in embodiments, where the connection means 116 comprises a threaded exterior surface on a tapered side wall of the top portion 110, the receiving means 122 may comprise an inverse threaded surface 124 for receiving the threaded surface of the connection means 116, as well as an inversely tapered side wall as shown in the Figure. It should be appreciated, for embodiments of the present disclosure, for each type of connection means 116 disclosed herein, and variations thereof, the receiving means 122 may be structurally inverse thereto.

In many embodiments, to allow for ease of alignment with adjacent nestable beverage containers, as described hereinbelow, many of the components of the nestable beverage containers may be symmetrical about a central axis C-C passing through the center of top portion 110, the bottom portion 120, and the voluminous body 130. In certain embodiments, however, it is understood it may not be practical to have each and every component symmetrical thereon, for example, where the nestable beverage container is similar to a traditional soda can, the single opening thereof is positioned off-center.

FIG. 5 depicts a system of nested beverage containers in accordance with embodiments of the present disclosure. The system 500 generally comprises at least a first nestable beverage container 100 and a second nestable beverage container 200. In certain embodiments, however, a third nestable beverage container 300 up to n nested beverage containers, wherein n is any number feasible within the context of embodiments of the present disclosure, may be provided within the system 500.

Each of the nestable beverage containers within the system 500 generally comprise a top portion, a bottom portion and a voluminous body, as described hereinabove. To create system 500, however, once each of the nestable beverage containers is provided, e.g., the first nestable beverage container 100 and the second nestable beverage container 200, the connection means 216 of the second beverage container 200 is securely engaged with the receiving means 122 of the first beverage container 100. As shown, the connection means 216 comprises a threaded surface on an exterior surface of the second nestable beverage container 200, and the receiving means 122 comprises a corresponding inverse threaded surface for receiving the connection means 216.

Similarly, in system 500, where a third nestable beverage container 300 is provided, the connection means 316 of the third beverage container 300 is securely engaged with the receiving means 222 of the second beverage container 200. As shown, the connection means 316 comprises a threaded surface on an exterior surface of the third nestable beverage container 300, and the receiving means 222 comprises a corresponding inverse threaded surface for receiving the connection means 316.

In many embodiments, system 500 may comprise nestable beverage containers, similarly structured with the exception of the sealing means on each nestable beverage container. For example, in embodiments, system 500 may comprise a first nestable beverage container 100 comprising a sealing means 114 comprising a threaded cap, as described hereinabove. In the same embodiment, however, the second nestable beverage container 200 may comprise a sealing means 214 comprising a peelable tab over the opening thereof, as well as having a threaded exterior surface for receiving a threaded cap, despite no cap necessarily being provided thereon.

In such an exemplary embodiment, the user of the system 500 may be able to consume the contents of the first nestable beverage container 100, separate the first nestable beverage container 100 from the system 500, and from the connection means 216 of the second nestable beverage container 200. The first nestable beverage container 100 may then be securely engaged using the connection means 116 with the receiving means 322 of the third nestable beverage container 300. In addition, the user may optionally remove the threaded cap of the sealing means 114. The user may then remove the peelable tab of the sealing means 214 and replace it with the threaded cap. Generally, in such an embodiment, the third nestable beverage container 300 will also comprise a sealing means comprising a peelable tab. As such, the user will be able to have a resealable threaded cap on whichever of the nestable beverage containers is the topmost container within the system 500.

Optionally, with embodiments of the present disclosure, when a plurality of nestable beverage containers are engaged within a system 500, each of the side walls of the respective nestable beverage containers align to form a substantially continuous side wall 532. It should be appreciated, however, where certain embodiments of the present disclosure may not comprise nestable beverage containers having constant diameter or shaped side walls, the alignment of adjacent sidewalls may only comprise the alignment of the bottom portion of a first nestable beverage container 100 with the sidewall of a second nestable beverage container, such that it may not be readily identifiable upon an initial glance where a first nestable beverage container ends and the second nestable beverage container begins.

Although FIGS. 2-5 depict a nestable beverage container in the general form of a bottle, FIG. 6 depicts a side view of a nestable beverage container in accordance with embodiments of the present disclosure. FIG. 6 depicts a nestable beverage container 600 substantially in the shape of a traditional soda can, such as the one shown in FIG. 1. However, similar to the embodiments depicted in FIGS. 2-5, the nestable beverage container 600 comprises a top portion, a bottom portion and a voluminous body 630, wherein the voluminous body 630 is defined by the top portion, the bottom portion and a side wall 632.

The top portion generally comprises an opening 612 into the voluminous body 630, a sealing means 614, and a connection means 616 positioned beneath the sealing means 614. In the exemplary embodiment, the sealing means 614 comprises a tab and semi-weakened surface covering the opening 612. However, any of the aforementioned sealing means may be suitable for the exemplary embodiment as well. As shown, the connection means 616 comprises a threaded surface on the exterior of the nestable beverage container 600. Similarly, however, any of the aforementioned connection means may be suitable for the exemplary embodiment.

The receiving means 622 of the nestable beverage container 600 may comprise any suitable structure to adapt to the connection means 616, for example, an inversely threaded surface 624 to receive and securely engage the connection means of an adjacent nestable beverage container.

FIG. 7 depicts a system of nested beverage containers in accordance with embodiments of the present disclosure. The system 700 generally comprises at least a first nestable beverage container 600 and a second nestable beverage container 800. In certain embodiments, however, up to n nested beverage containers, wherein n is any number feasible within the context of embodiments of the present disclosure, may be provided within the system 700.

Each of the nestable beverage containers within the system 700 generally comprise a top portion, a bottom portion and a voluminous body, as described hereinabove. To create system 700, however, once each of the nestable beverage containers is provided, e.g., the first nestable beverage container 600 and the second nestable beverage container 800, the connection means 816 of the second beverage container 800 is securely engaged with the receiving means 622 of the first beverage container 600. As shown, the connection means 816 comprises a threaded surface on an exterior surface of the second nestable beverage container 800, and the receiving means 622 comprises a corresponding inverse threaded surface for receiving the connection means 816.

In many embodiments, it may be desirable to affix a non-beverage item to the bottom and/or top of a beverage container. For example, it may be desirable to package food with a beverage. In embodiments, it may be desirable to affix a can of peanuts to a beer can. In another embodiment, it may be desirable to affix a can of popcorn (popped or unpopped) to a can of soda. In yet another embodiment, it may be desirable to affix a container of ice or ice pack to the bottle and/or top of any beverage container. In a further embodiment, it may be desirable to affix crackers to a can of soup.

In accordance with embodiments of the present disclosure, the second nestable beverage container 800, as shown in FIG. 7, may be utilized as a non-beverage container for storing food or other articles. Depending on the nature of the food or other articles, the size and shape of the second nestable container may vary to fit a particular application. In embodiments, the height of the second nestable container may be shorter than the first nestable beverage container. In another embodiment, the second nestable container may be any variation of shape provided it comprises a means for connecting to the receiving means of the first nestable beverage container. For example, in embodiments, where an ice pack is desired to be affixed to a beer can, the ice pack may be provided in the shape of an insulated holder (commonly known as a coozie), having a connection means positioned on a surface thereof positioned against the bottom of the first nestable beverage container (e.g., the beer can).

In other embodiments, depending on the nature of the non-beverage product being stored, the second nestable container may comprise a different sealing means than the first nestable container. For example, where a beer and peanuts are being stored together, the beer can may comprise a pull tab-type sealing means, as described in FIG. 1, whereas the peanut can may comprise a peelable tab sealing means. Such peelable tab may comprise a piece of foil or similar material shaped to fit over an entire opening of the second nestable container, and removably affixed thereon by adhesive or similar cohesive agent. A tab of foil, or similar material, extends from the top of the piece of foil near an outer edge thereof, and upon pulling the tab, the piece of foil can be removed. Such a peelable tab is commonly used on food products, pharmaceutical products, etc., to ensure security of the products contained therein.

FIG. 8 depicts a carrier for packaging a system of nested beverage containers in accordance with embodiments of the present disclosure. As shown in the Figure, the carrier 850 generally comprises a support portion 860 having at least one aperture 862 therethrough, and an optional handle portion, for example, handle 870. In an alternative embodiment, the handle 870 may comprise a perpendicular projection from the top of the support portion 860.

In accordance with embodiments of the present disclosure, a system of nestable containers, as shown in FIG. 7, may be carried via the carrier 850. In such an embodiment, the connection means of the second container may be placed through the aperture 862 before engaging the receiving means of the first container. In doing so, the carrier 850 effectively becomes locked between the two containers.

The carrier may be provided with anywhere from one to any number of apertures 862 in the support portion 860. In one commercial embodiment, the carrier may be provided with any of three, six, nine, twelve or fifteen apertures 862, permitting the overall system to provide six, twelve, eighteen, twenty-four or thirty containers therein, which are traditionally the quantity by which carbonated beverages such as soda, seltzer, and/or beer is sold.

The carrier may be made from any of plastic, metal, cardboard, organic materials, combinations thereof or the like. In many embodiments, the carrier is manufactured from cardboard or reinforced/corrugated cardboard, capable of supporting the quantity of containers thereon. In embodiments, the support platform 860 may comprise a first material, and the handle portion 870 another material. For example, the support platform 860 may comprise a cardboard material, while the handle comprises a rope, such as a hemp rope. In many of such embodiments, the carrier materials may be biodegradable or otherwise environmentally friendly.

FIG. 9 depicts a tray for packaging a system of nested beverage containers in accordance with embodiments of the present disclosure As shown in the Figure, the tray 900 may generally comprise a tray platform 910 and at least one connection means 920. The connection means 920 may comprise any of the types of connection means discussed herein, for adapting to a receiving means of a nestable container (not shown). In accordance with embodiments of the present disclosure, any number of connection means 920 may be provided on a single tray 900. Optionally, the tray may further comprise a flat and/or recessed portion 930 for placing miscellaneous items thereon.

In many embodiments, the tray may be utilized to temporarily carry a nestable container as well as additional items. For example, at a baseball game, a patron may desire to grab a couple sodas and some food. By utilizing a tray, as disclosed herein, the patron may be able to secure the sodas provided in a nestable container as described herein, while placing the food on the flat portion 930 of the tray 900. By having the nestable containers affixed therein, the patron may be able to prevent spills, dropped cups/cans/bottles, and the like, when walking or moving with the tray 900.

FIG. 10 depicts a side view of a system of nestable beverage containers 1100 in accordance with embodiments of the present disclosure and FIG. 11 depicts cross-sectional view of a nestable beverage container 1102 depicted in FIG. 10. A nestable beverage container 1100 generally comprises a top portion 1110, a bottom portion 1120 and a voluminous body 1130. The voluminous body 1130 is generally defined by the top portion 1110, the bottom portion 1120 and a side wall 1132. The system of beverage containers 1100 may comprise a top bottle 1101, a central bottle 1102, a bottom bottle 1103, the central bottle 1102 generally disposed between the top bottle 1101 and a bottom bottle 1103. While three bottles are depicted, more or less bottles may be included in the system 1100, for example, two, four, six, or eight bottles may be included. The system may generally include a single top bottle 1101 and a single bottom bottle 1103. In embodiments the system 1100 a number of central bottles 1102 nested between the top bottle 1101 and the bottom bottle 1103. In embodiments, the shapes and sizes of the bottles may vary to achieve a uniform storage capacity within the voluminous body 1130 of each bottle. For example, bottles with receiving means 1122 may be longer and/or wider than bottles without receiving means 1122 to make up for the lost storage space caused by the receiving means 1122. In embodiments, a system 1100 may comprise bottles 1101, 1102, 1103 that are shaped similarly or the same, wherein the storage volume of each bottles 1101, 1102, 1103 may be different.

The nestable beverage containers 1101, 1102, 1103 may comprise any materials suitable for embodiments of the present disclosure. In embodiments, the nestable beverage containers 1101, 1102, 1103 comprises at least one of a polymer, a metal, a metal alloy, glass, combinations thereof or the like.

The top portion 1110 generally comprises an opening 1112 into the voluminous body 1130. In accordance with many embodiments of the present disclosure, the opening 1112 is the only means for accessing an interior of the voluminous body 1130 and any contents of the nestable beverage container 1102.

Generally, the top portion 1110 also comprises a sealing means 1114. The sealing means 1114 may comprise any structure suitable to control access to an interior of the voluminous body 1130. In embodiments, the sealing means 1114 comprises a threaded surface and an inversely threaded cap for removably sealing the opening 1112 of the nestable beverage container 1102. In some embodiments, the sealing means 1114 may comprise a twist off or pry off cap, or the like. In another embodiment, the sealing means 1114 comprises a tab and semi-weakened surface covering the opening 1112. In further embodiments, the sealing means 1114 may comprise a peelable tab, wherein the peelable tab is removably affixed over the opening 1112 by an adhesive or similar type of cohesion agent. Such type of peelable tabs are commonly utilized as security or tampering devices on various food and beverage products.

In yet another embodiment, the sealing means 1114 may comprise a snap-locking cap about a correlating annular tab surrounding the opening 1112. In yet further embodiments, the sealing means 1114 may comprise a closeable cap, for example, as found on sports drinks, whereby the concept of a threaded cap and surface combination is further complimented by a controllable opening in the cap itself. In such embodiments, the closeable cap may also comprise a dust cap, protecting the portion of the cap from undesirable contaminants.

In many embodiments of the present disclosure, the top portion 1110 further comprises a connection means 1116 for allowing the nestable beverage container 1102 to be nested within an adjacent nestable beverage container. In embodiments, the connection means comprises a threaded surface on an exterior of the nestable beverage container. In exemplary embodiments, the connection means 1116 may comprise a threaded surface on an exterior of the neck of a beverage bottle. The neck may be substantially elongated, for example, the neck may comprise the neck of a beer bottle. In embodiments, the threaded surface may extend down from a position just beneath the sealing means 1114. In another embodiment, the connection means 1116 may comprise a threaded surface on the exterior surface of the sealing means 1114. For example, where the sealing means 1114 comprises a threaded cap as described above, the connection means 1116 may comprise a threaded surface on the exterior of the threaded cap. In embodiments, the threaded surface may be disposed substantially lower on the container 1102 than the sealing means 1114. In yet further embodiments, the connection means 1116 may comprise an annular projection from the exterior surface of the nestable beverage container 1102, for engaging a snap-fit type structure in an adjacent nestable beverage container.

In another embodiment of the present disclosure, the connection means 1116 may comprise an annular ring having at least one tab projecting outward from the nestable beverage container. In such an embodiment, the at least one tab may be adapted to fit within an inverse receptive pattern with an adjacent nestable beverage container. Generally, when the tab is inserted into the receptive pattern on the adjacent nestable beverage container, with a short rotation (e.g., quarter turn, half turn, etc.) the tab may be positioned securely within the receptive pattern on the adjacent nestable beverage container. Generally, a plurality of tabs are provided in such types of embodiments.

In yet further embodiments of the present disclosure, the connection means 1116 may comprise a specific structural design (e.g., tapering neck, hour-glass shape, etc.) of the outer surface of the top portion 1110 to create a friction-type fit with an adjacent nestable beverage container.

The bottom portion 1120 may generally comprise a receiving means 1122 shaped to conform to the connection means 1116 of an adjacently nested beverage container. In many embodiments, the receiving means 1122 is substantially an inverse structure of the connection means 1116, as positioned on the top portion 1110. For example, in embodiments, where the connection means 1116 comprises a threaded exterior surface on a tapered side wall of the top portion 1110, the receiving means 1122 may comprise an inverse threaded surface 1124 for receiving the threaded surface of the connection means 1116, as well as an inversely tapered side wall as shown in the Figures. It should be appreciated, for embodiments of the present disclosure, for each type of connection means 1116 disclosed herein, and variations thereof, the receiving means 1122 may be structurally inverse thereto.

In embodiments of the present disclosure, a system 1100 may comprise bottles 1101, 1102, 1103 that comprise different elements. For example, the system 1110 may comprise a top bottle 1101 that comprises a receiving means 1122 but does not comprise a connection means. The top bottle 1101 may not comprise a connection means because additional bottles may be intended to be placed underneath, not on top of, the top bottle 1101. The lack of a connection means in the top bottle 1101 may remove protrusions from the surface 1132 of the top bottle 1101, whereby the grip on the bottle is improved and the risk of dropping the top bottle 1101 or system 1110 is reduced.

The central bottle 1102 may comprise a connection means 1116 adapted to attach, and/or couple with, a receiving means 1122 of a top bottle 1101 or another central bottle. The central bottle 1102 may comprise a receiving means 1122 adapted to couple with a connection means 1116 of a bottom bottle 1103 or another central bottle. The central bottle 1102 may comprise a sealing means 1114, such as a cap, that may remain in place when the central bottle 1102 is nested within the top bottle 1101, in another central bottle, or the like.

In embodiments, the system 1100 may comprise additional central bottles 1102. The central bottle 1102 may be nested within the top bottle 1101 or another central bottle. In embodiments, a bottom bottle 1103 may comprise a connection means 1116 but not a receiving means. The bottom bottle 1103 may not comprise a receiving means because additional bottles may be intended to be placed above, not below the bottom bottle 1103. The lack of a receiving means in the bottom bottle 1103 may remove protrusions from the surface 1132 of the bottom bottle 1103, whereby the grip on the bottle is improved and the risk of dropping the bottom bottle 1103 or system 1110 is reduced. The bottom bottle 1103 may comprise a sealing means 1114, such as a cap, that may remain in place when the bottom bottle 1103 is nested within the top bottle 1101, a central bottle 1102, or the like.

In embodiments, bottom portion 1120 of a bottle 1102 (i.e. a nested or lower portion), may comprise an external sealing means 1114, such as a cap disposed on the neck portion of the bottle 1102 while the bottle 1102 is in the nested position and nested in the bottom portion 1120 of an additional bottle, for example, the top bottle 1101. The sealing means 1114, such as a cap, may be securely engaged with a neck of the bottle 1102 when the connection means 1116 is securely engaged with a second receiving means 1122 on a bottom portion of a second nestable beverage bottle. As such, a cap may remain in place on a lower bottle when it is stacked under/nested within an upper bottle, and the upper bottle may comprise a void or area adapted to receive the cap.

In many embodiments, to allow for ease of alignment with adjacent nestable beverage containers, as described hereinbelow, many of the components of the nestable beverage containers may be symmetrical about a central axis passing through the center of top portion 1110, the bottom portion 1120, and the voluminous body 1130. In certain embodiments, however, it is understood it may not be practical to have every component symmetrical thereon, for example, where the nestable beverage container is similar to a traditional soda can, the single opening thereof is positioned off-center. Although a system 1100 of bottles is depicted in FIG. 10, it is contemplated that alternative containers may be used. For example, instead of bottles 1101, 1102, 1103, cans of the same or similar components, i.e., a sealing means and/or connection means may be used. In embodiments, the cans may be adapted to be opened with a tab, or the like, or may comprise an aluminum can adapted to be opened with a can opener, or the like.

FIG. 12 depicts a side view of nestable beverage containers 1200 in accordance with embodiments of the present disclosure. Nestable beverage containers 1200 generally comprise a top portion, a bottom portion and a voluminous body, as described supra with respect to other embodiments shown in at least FIGS. 6 and 7. A voluminous body may generally defined by the top portion, the bottom portion and a side wall. The system of beverage containers 1200 may comprise a top container 1220, a central container 1230, a bottom container 1240, the central container 1230 generally disposed between the top container 1220 and a bottom container 1240. While three containers are depicted, additional or fewer containers may be included in the system 1200, for example, two, four, six, or eight containers may be included. In embodiments, the containers may generally comprise cans, buckets, cylindrical containers, square containers, or the like.

The system may generally include a single top container 1220 and a single bottom container 1240. In embodiments the system 1200 a number of central containers 1230 nested between the top container 1220 and the bottom container 1240 may be any number suitable for embodiments of the present disclosure, for example, 0, 1, 2, 3, 5, 6, 10, or the like. In embodiments, the shapes and sizes of the containers may vary to achieve a uniform storage capacity within the voluminous body of each container. For example, containers with receiving means 1222 may be longer and/or wider than containers without receiving means, such as the bottom container 1240, to make up for lost storage space due to the presence of the receiving means 1222. In embodiments, a system 1200 may comprise containers 1220, 1230, 1240 that are shaped similarly or the same, wherein the storage volume of each containers 1220, 1230, 1240 may be the same or different to accommodate any changes in volume caused by the receiving means 1222, or the like. In embodiments, the containers 1220, 1230, and 1240 may comprise substantially the same shape, different shapes, combinations thereof, or the like.

The nestable beverage containers 1220, 1230, 1240 may comprise any materials suitable for embodiments of the present disclosure. In embodiments, the nestable beverage containers 1220, 1230, 1240 comprises at least one of a polymer, a metal, a metal alloy, glass, plastic, combinations thereof or the like. A top portion 1216 may generally comprises an opening 1212 into the voluminous body 1250. In accordance with many embodiments of the present disclosure, the opening 1212 is the only means for accessing an interior of the voluminous body 1250 and any contents of the nestable beverage container 1230.

Generally, the top portion 1216 also comprises a sealing means 1214. In embodiments, the sealing means 1214 may comprise a pull tab and a semi-weakened surface for sealing the opening, the semi-weakened surface capable of being opened by the pull tab, or the like. The sealing means 1214 may comprise any structure suitable to control access to an interior of the voluminous body 1250. In further embodiments, the sealing means 1214 may comprise a peelable tab, wherein the peelable tab is removably affixed over the opening 1212 by an adhesive or similar type of cohesion agent. Such types of peelable tabs are commonly utilized as security or tampering devices on various food and beverage products.

In yet another embodiment, the sealing means 1214 may comprise a snap-locking cap about a correlating annular tab surrounding the opening 1212. In yet further embodiments, the sealing means 1214 may comprise a closeable cap, for example, as found on sports drinks, whereby the concept of a threaded cap and surface combination is further complimented by a controllable opening in the cap itself. In such embodiments, the closeable cap may also comprise a dust cap, protecting the portion of the cap from undesirable contaminants. In embodiments, the containers 1200 may comprise jars, or the like, with lids that may be screwed on, snapped on, or otherwise attached to cover an opening in the jar, or the like.

In many embodiments of the present disclosure, the top portion 1216 further comprises a connection means 1236 for allowing the nestable beverage container 1230 to be nested within an adjacent nestable beverage container. In embodiments, the connection means 1236 comprises a threaded surface on an exterior of the nestable beverage container. In embodiments, the connection means 1236 may comprise one or more protruding structures or tabs adapted to couple with the receiving means 1222. The receiving means 1222 may also be adapted to receive and couple with the connection means 1236.

In exemplary embodiments, a connection means 1236 may comprise a threaded surface on an exterior of the neck of a beverage container. In embodiments, the threaded surface may extend down from a position just beneath the sealing means 1214. In another embodiment, the connection means 1236 may comprise protrusions disposed on an outer portion of the top portion 1216, or the like. In yet further embodiments, the connection means 1236 may comprise an annular projection from the exterior surface of a nestable beverage container, for engaging a snap-fit type structure in an adjacent nestable beverage container.

In another embodiment of the present disclosure, the connection means 1236 may comprise an annular ring having at least one tab projecting outward from the nestable beverage container. In such an embodiment, the at least one tab may be adapted to fit within an inverse receptive pattern with an adjacent nestable beverage container. Generally, when the tab is inserted into the receptive pattern on the adjacent nestable beverage container, with a short rotation (e.g., quarter turn, half turn, etc.) the tab may be positioned securely within the receptive pattern on the adjacent nestable beverage container. Generally, a plurality of tabs may be provided in such embodiments, or the like.

In yet further embodiments of the present disclosure, the connection means 1236 may comprise a specific structural design (e.g., tapering neck, hour-glass shape, etc.) of the outer surface of the top portion 1216 to create a friction-type fit with an adjacent nestable beverage container.

A bottom portion 1218 may generally comprise a receiving means 1222 shaped to conform to the connection means 1236 of an adjacently nested beverage container. In embodiments, not all containers in the system 1200 may be identical. For example, some containers may comprise a connection means 1236 and a receiving means 1222 (such as the central container 1230), some containers may comprise a connection means 1236 and not a receiving means (such as the bottom container 1240), and some containers may comprise a receiving means 1222 and not a connection means (such as the top container 1220). A variation in can types is also contemplated in all embodiments disclosed by and within the present disclosure.

In many embodiments, the receiving means 1222 is substantially an inverse structure of the connection means 1236, as positioned on the top portion 1216. For example, in embodiments, where the connection means 1236 comprises a threaded exterior surface on a tapered side wall of the top portion 1216, the receiving means 1222 may comprise an inverse threaded surface 1224 for receiving the threaded surface of the connection means 1236, as well as an inversely tapered side wall. It should be appreciated, for embodiments of the present disclosure, for each type of connection means 1236 disclosed herein, and variations thereof, the receiving means 1222 may be structurally inverse thereto and/or may be adapted to otherwise couple with each other through mechanical methods. In embodiments, when assembled the system 1200 may produce a single continuous side wall 1232, or the like.

In embodiments of the present disclosure, a system 1200 may comprise containers 1220, 1230, 1240 that comprise different elements. For example, the system 1210 may comprise a top container 1220 that comprises a receiving means 1222 but does not comprise a connection means. The top container 1220 may not comprise a connection means because additional containers may be intended to be placed underneath, not on top of, the top container 1220. The lack of a connection means in the top container 1220 may remove protrusions from the surface 1232 of the top container 1220, whereby the grip on the container is improved and the risk of dropping the top container 1220 or system 1210 is reduced. In embodiments, each container may comprise the same or different sealing means 1214, combinations thereof, or the like.

The central container 1230 may comprise a connection means 1236 adapted to attach, and/or couple with, a receiving means 1222 of a top container 1220 or another central container. The central container 1230 may comprise a receiving means 1222 adapted to couple with a connection means 1236 of a bottom container 1240 or another central container. The central container 1230 may comprise a sealing means 1214, such as a cap, that may remain in place when the central container 1230 is nested within the top container 1220, in another central container, or the like.

In embodiments, the system 1200 may comprise additional central containers 1230. The central container 1230 may be may be nested within the top container 1220 or another central container. In embodiments, a bottom container 1240 may comprise a connection means 1236 but not a receiving means. The bottom container 1240 may not comprise a receiving means because additional containers may be intended to be placed above, not below the bottom container 1240. The bottom container 1240 may comprise a sealing means 1214, such as a weakened portion and pull tab combination, that may remain in place when the bottom container 1240 is nested within the top container 1220, a central container 1230, or the like.

In embodiments, bottom portion 1218 of a container 1230 (i.e. a nested or lower portion), may comprise an external sealing means 1214, such as a cap disposed on the top portion of the container 1230 while the container 1230 is in the nested position and nested in the bottom portion 1218 of an additional container, for example, the top container 1220. The sealing means 1214, such as a cap, may be securely engaged with a neck of the container 1230 when the connection means 1236 is securely engaged with a second receiving means 1222 on a bottom portion of a second nestable beverage container. As such, a cap may remain in place on a lower container when it is stacked under/nested within an upper container, and the upper container may comprise a void or area adapted to receive the cap.

In many embodiments, to allow for ease of alignment with adjacent nestable beverage containers, as described herein, many of the components of the nestable beverage containers may be symmetrical about a central axis passing through the center of top portion 1216, the bottom portion 1218, and the voluminous body 1250. In certain embodiments, however, it is understood it may not be practical to have each and every component symmetrical thereon, for example, where the nestable beverage container is similar to a traditional soda can, the single opening thereof is positioned off-center. Although a system 1200 of containers is depicted in FIG. 12, it is contemplated that alternative containers may be used. For example, instead of containers 1220, 1230, 1240, bottles of the same or similar components, i.e., a sealing means and/or connection means may be used. In embodiments, the cans may be adapted to be opened with a tab, or the like, or may comprise a can with no openings, the can adapted to be opened with a can opener, or the like.

FIG. 13 depicts a side view of nestable beverage container system 1300 in accordance with embodiments of the present disclosure. The beverage containers system 1300 may comprise two or more containers 1301, 1303 adapted to couple with each other. In the example depicted in FIG. 13, two bottles 1301, 1303 are depicted, however any number of bottles and/or other containers suitable for embodiments of the present disclosure are contemplated. In the example depicted in FIG. 13, a top bottle 1301 and a bottom bottle 1303 may combine to form a nestable beverage container system 1300 that may hold a volume of liquid typical in standard bottles. For example, a standard beer bottle may hold 12 fluid ounces. In embodiments, the nestable beverage container system 1300 may combine to hold 12 fluid ounces, or the like. For example, the top bottle 1301 may hold 6 ounces and the bottom bottle 1303 may hold 6 ounces of liquid, or the like. In another embodiment, the top bottle 1301 may hold 4 ounces and the bottom bottle 1303 may hold 8 ounces, or the like, that may be substantially equivalent to the 12 ounces, or the amount a standard container holds.

In exemplary embodiments, the nestable beverage container system 1300 may comprise an opening 1312 into the individual containers 1301, 1303, a sealing means 1314 for sealing the opening 1312, a sidewall 1332 defining a volume of the containers, and a connection means 1316 for coupling with a receiving means 1322 of an adjacent nested bottle. Examples of the opening 1312, sealing means 1314, sidewall 1332, connection means 1316, and receiving means 1322 are described herein with respect to the other figures. For example, the connection means 1316 and receiving means 1322 may comprise inversely threaded portions adapted to couple with each other to join adjacent bottles 1301, 1303. The sealing means 1314 may be a cap, or the like, and may not comprise a threaded portion, wherein the receiving means 1322 of an adjacent bottle comprises a cavity adapted to accept and receive the cap, or the like. As shown in the example in FIG. 14, in exemplary embodiments, each bottle in the system 1300 need not be identical. For example, the top bottle 1301 may comprise a receiving means 1322 but not a connection means 1316. The bottom bottle 1301 may comprise a connection means 1316 but not a receiving means 1322. In exemplary embodiments, two smaller bottles 1301, 1303 may be coupled together to form a single standard sized bottle, or the like.

FIG. 14 depicts a side view of nestable beverage containers 1400 in accordance with embodiments of the present disclosure. The beverage containers system 1400 may comprise two or more containers 1401, 1403 adapted to couple with each other. In the example depicted in FIG. 14, two cans 1401, 1403 are depicted, however any number of cans and/or other containers suitable for embodiments of the present disclosure are contemplated. In the example depicted in FIG. 14, a top can 1401 and a bottom can 1403 may combine to form a nestable beverage container system 1400 that may hold a volume of liquid typical in standard cans. For example, a standard beer can may hold 12 fluid ounces. In embodiments, the nestable beverage container system 1400 may combine to hold 12 fluid ounces, or the like. For example, the top can 1401 may hold 6 ounces and the bottom can 1403 may hold 6 ounces of liquid, or the like. In another embodiment, the top can 1401 may hold 4 ounces and the bottom can 1403 may hold 8 ounces, or the like, that may be substantially equivalent to the 12 ounces, or the amount a standard container holds. The top can 1401 and bottom can 1403 may couple together to form a visually seamless sidewall, wherein a parts of an image 1410, such as a label, picture, text, logo, or the like may be printed across both cans 1401, 1403 to form the single complete image 1410 when the cans 1401, 1403 are combined.

In exemplary embodiments, the nestable beverage container system 1400 may comprise an opening 1412 into the individual containers 1401, 1403, a sealing means 1414 for sealing the opening 1412, a sidewall 1432 defining a volume of the containers, and a connection means 1416 for coupling with a receiving means 1422 of an adjacent nested can. Examples of the opening 1412, sealing means 1414, sidewall 1432, connection means 1416, and receiving means 1422 are described herein with respect to the other figures. For example, the connection means 1416 and receiving means 1422 may comprise inversely threaded portions adapted to couple with each other to join adjacent cans 1401, 1403. The sealing means 1414 may be a weakened portion and a tab adapted to open the weakened portion, or the like, wherein the receiving means 1422 of an adjacent can comprises a cavity adapted to accept and receive the tab, or the like. As shown in the example in FIG. 14, in exemplary embodiments, each can in the system 1400 need not be identical. For example, the top can 1401 may comprise a receiving means 1422 but not a connection means 1416. The bottom can 1401 may comprise a connection means 1416 but not a receiving means 1422. In exemplary embodiments, two smaller cans 1401, 1403 may be coupled together to form a single standard sized can, or the like.

FIG. 15 depicts a side view of nestable beverage containers 1500 in accordance with embodiments of the present disclosure. The examples shown in FIG. 15 are substantially identical to the example cans depicted in FIG. 14, with the exception that no opening is present, and the top can 1502 and the bottom can 1504 comprise a substantially flat top surface 1550, 1552 and no opening. Cans of this type would need to be opened with a can opener, or the like. The cans 1550, 1552 connect in the same way as described with respect to FIG. 14.

FIG. 16 depicts a top perspective view of a stackable and nestable beverage container 1600 in accordance with embodiments of the present disclosure. In exemplary embodiments, a top portion 1610 may be substantially equivalent to the examples of cans described herein with the exception of the connection means 1620. For example, the top portion 1610 may comprise a weakened portion and a pull tab, a peelable tab covering an opening, or no opening at all. In embodiments where the container 1600 does not contain an opening on the top portion 1610, a can opener or similar device may be used to open the container 1600. In embodiments, the container 1600 may also comprise an upper rim 1650 or flange extending upwardly from the side wall 1632 of the container 1600. An upper rim 1650 may extend from the side wall 1632, the top portion 1610, and/or the like. The upper rim 1650 may be positioned at a perpendicular angle to the top portion 1610 or at any angle generally between 0 and 180 degrees with respect to a plan formed by the top portion 1610 of the container 1600, or the like.

In embodiments, the upper rim 1650 may comprise a generally rounded shape, and may be adapted to fit within and/or be nested within an adjacent container. The side wall 1632 may be equivalent to a side wall of a standard can or the side wall in accordance with embodiments described herein supra. The upper rim 1650 may be generally annular or circular and rise above a top surface at the center of the top portion 1610 of the can. The upper rim 1650 in standard cans may be adapted to contain a portion of liquid that overflows or spills onto the top portion 1610 of the can within the upper rim 1650.

In some exemplary embodiments, the upper rim 1650 may comprise one or more connection means 1620 adapted to attach the container 1600 to an adjacent nestable can, or the like. In some exemplary embodiments, the connection means 1620 may comprise protrusions or tabs that protrude, angle, and/or bend outwardly or inwardly from an outermost surface of an upper rim 1650 or flange of a container 1600 away from or toward a central axis running vertically through the center of the can, or the like. Although three connection means 1620 are depicted in FIG. 16, any number of connection means 1620 suitable for embodiments of the present disclosure adapted to couple a container 1600 with a second container are contemplated.

A connection means 1620 may be formed generally to couple with a receiving means (see FIG. 17) of a second adjacent container, thereby allowing the container 1600 to be nested within the adjacent beverage container. In embodiments, a connection means 1620 may comprise one or more projections from the exterior surface of the top portion 1610 or upper rim 1650. In embodiments, the projections of the connection means 1620 may protrude at an angle between 0 and 90 degrees from a vertical plane defined by the outer surface of the upper rim 1650. The connection means 1620 may protrude outwardly or inwardly toward the center of the container 1600. In embodiments, the protrusion may comprise a hook-like structure, a snapping structure, or a downward facing tab configured to couple with a receiving means of a second container, or the like.

In embodiments, the connection means 1620 or at least one tab or projection may be adapted to fit within a receiving means of an adjacent container. A receiving means may comprise an inverse receptive pattern with an adjacent nestable beverage container. Generally, when the tab is inserted into the receptive pattern on the adjacent nestable beverage container, with a short rotation (e.g., quarter turn, half turn, etc.) the tab may be positioned securely within the receptive pattern on the adjacent nestable beverage container. Generally, a plurality of tabs are provided in such types of embodiments. An exemplary receiving means is depicted in FIG. 17.

FIG. 17 depicts a bottom perspective view of the nestable beverage container 1600 shown in FIG. 16 in accordance with embodiments of the present disclosure. In addition to the components described with respect to FIG. 16, the container 1600 may also comprise a receiving means 1752. The number and location of the receiving means 1762 may formed in an equal number and corresponding location to the connection means 1620 on the top portion 1610. In the example shown in FIGS. 16 and 17, the connection means 1620 may be a protrusion from the upper rim 1620 and the receiving means 1752 may be formed in an inverse receptive pattern allowing the connection means 1620, or the like, to slide in a groove 1720 formed in a lower rim 1750 of the container 1600. The lower rim 1750 may be generally annular in shape and may extend downwardly away from the side wall 1632. The connection means 1620 may fit in the lower rim 1750 or may be a separate component affixed to the lower rim, for example, with adhesive, by friction fit, and/or the like.

In exemplary embodiments, a can 1600 may comprise one or more connection means 1620 which may comprise protrusions on an upper rim 1650 of the container 1600. The protrusions on the upper rim 1650 of the container 1600 may comprise any number suitable for embodiments of the present disclosure. For the example, the container may comprise three connection means 1620 comprising protrusions. The connection means 1620 may be adapted to fit within a receiving means 1752 of an adjacent container. The receiving means 1752 may comprise a channel, or the like, adapted to receive the connection means 1620 and allow the connection means 1620 to slide within the receiving means 1752 until it reaches the top of a lower rim 1750 positioned on the lower portion 1718 of the can. In embodiments, the lower rim 1750 may be integral with the side wall 1632 of the container 1600, or the like.

In embodiments, after the connection means 1620 is positioned within the receiving means 1752 and reaches the top of the lower rim 1750, the container 1600 may then be slid within a track 1725 positioned on the top of the interior portion of the lower rim 1750, or the like. In embodiments, the connection means 1620 or protrusions may fit within the track 1725 to secure adjacent containers together. The connection means 1620 may slide within the track 1725 of an adjacent can when the user turns the can until the connection means 1620 or protrusion contacts a stop 1754, or the like, thereby preventing the can from turning further. The stop 1754 may comprise a protrusion or bump, or may simply comprise the end of the track 1725. In embodiments, the track 1725 may be an indentation, groove, or the like, sized to fit the connection means 1620 or protrusion, on the interior surface of the lower rim 1750, or the like. The number of tracks 1725 may generally correspond to the number of connection means 1620 of a container 1600, or the like.

In embodiments, when a connection means 1620 is positioned within a track 1725 of an adjacent container, the containers are prevented from dislodging or disconnecting until the user turns the can in such a manner that reverses the connection means 1620 back out of the track 1725 and out of the receiving means 1752, by turning the can in an direction opposite the stops 1754, or the like. A stop 1754 may prevent the cans from being turned past a certain point. For example, the stop 1754 may allow the nested containers to turn up until a ¼ turn, a ⅓ turn, a ½ turn, or the like.

In operation, the user may align the connection means 1620 of a lower can with the receiving means 1752 of an upper can, slide the connection means 1620 of the lower can into the receiving means 1752 of the upper can until the connection means 1620 reaches the top of the lower rim 1750 of the upper can, turn the cans such that the connection means 1620 or protrusion slides within the track 1725 of the upper can until the connection means 1620 comes into contact with a stop 1754, or the like, stopping the rotation of the cans, thereby securing the lower can and the upper can together, wherein the upper rim 1650 of the lower can is nested, or the like, within the lower rim 1750 of the upper can, or the like. To separate the cans, the process may be reversed. The cans may be turn such that the connection means 1620 of the lower can may be reversed out of the track 1725 of the upper can, away from the stop 1754, then the connection means 1620 of the lower can may be slid downwardly through the receiving means 1752 of the upper can, away from the upper can, until the upper can and the lower can, or the like, are separated. In the examples depicted in FIGS. 16 and 17, the connection means 1620 and the receiving means 1752 are generally integral with the container 1600, however the connection means 1620 and/or receiving means 1752 may comprise separate pieces that may be connected to a standard can, container, or the like. FIGS. 18 and 19 depict examples wherein the connection means 1620 and/or receiving means 1752 are separate portions that may be attached to a standard can, container, and/or the like.

FIG. 18 depicts a top perspective view of a nestable beverage container 1800 in accordance with embodiments of the present disclosure. FIG. 19 depicts a bottom perspective view of the nestable beverage container 1800 shown in FIG. 18 in accordance with embodiments of the present disclosure. The example container 1800 shown in FIGS. 18 and 19 comprise a connection means 1820 comprises similar components to the cans described supra, and descriptions of common elements (side wall, top portion, bottom portion, sealing means, etc.) may be found supra and are not repeated here for purposes of brevity and clarity. It should be appreciated that any element of any example in any embodiment of the present disclosure can be used with any other element of any example in any embodiment of the present disclosure.

In embodiments, a container 1800 may comprise a separate upper connector 1852 and bottom connector 1854. The upper connector 1852 may comprise a connection means 1820 such as threading, protrusions, snaps, or any other example connection means consistent with the present disclosure. The lower connector 1854 may comprise a receiving means 1824 adapted to couple with the connection means 1820 and may comprise threading, slots, channels, or any mechanism adapted to couple with the connection means 1820 consistent with the present disclosure. In the example depicted in FIGS. 18 and 19, the upper connector 1852 may be adapted to connect, or be secured to an upper rim 1850 of a standard container, such as a can, or the like.

In exemplary embodiments, the lower connector 1854 may be adapted to connect, or be secured to and lower rim of a standard container, such as a can, or the like. An upper connector 1852 and/or a lower connector 1854 may comprise pieces separate from the can or container and/or be adapted to fit and or connect to a standard can. The upper connector 1852 and/or lower connector 1854 may be adapted to fit and/or form around an exterior surface of upper lip 1850 and/or lower lip of a standard can, or may fit within the interior surface of the lower lip and/or upper lip of a standard can. The connectors 1852, 1854 may be adapted to attach to the top and bottom of a standard container/or the like via friction fit, snap, protrusions, tracks, locking connectors, adhesive, and/or any method consistent with the present disclosure. The upper connector 1852 may comprise a connection means 1820 adapted to couple with the receiving means 1824 of a lower connector 1854 of an adjacent can, or the like. For example, a connection means 1820 on a first can may comprise a threading and a receiving means 1824 on an adjacent can may comprise an inverse threading such that the cans, or the like, may be coupled with each other. The connection means 1820 and receiving means 1824 may comprise any mechanism for connecting two cans consistent with the present disclosure.

FIGS. 20-38 depict various implementations of a container transport apparatus or portions of container transport apparatus in accordance with embodiments of the present disclosure. The example container transport apparatus implementations are designed and formed to carry beverage containers that are stackable or nestable in accordance with embodiments of the present disclosure. By way of example, the stackable cans depicted and described herein may be transported by a container transport apparatus depicted in FIGS. 20-38, or the like. Container transport apparatus implementations may comprise a handle, a support surface, and apertures through the support surface. The apertures may be sized, shaped, and adapted to accept a portion of a stackable or nestable beverage container or can. For example, a top potion of a stackable can may be inserted through the aperture and attached to a bottom portion of a second stackable can, thereby attaching the cans in a stacked or nested configuration in accordance with embodiments of the present disclosure. When the containers are attached in a stackable configuration through the aperture via a connection means as described herein, or the like, the container transport apparatus supports both cans disposed on opposite sides of the support surface, or the like.

Container transport apparatus implementations may be lifted and carried for transport via a handle, or the like. A handle may be sized to accept the hand of a user, or the like. Although depicted as protruding from the support surface in some figures, a handle may an aperture integral to the support surface and disposed within the boundaries of the support surface. In embodiments of the present disclosure a beverage transportation system may comprise the container transport apparatus and at least two beverages connected via a connection means as described herein, or the like. A container transport apparatus as shown may be adapted to carry cans in accordance with the present disclosure and any stackable or nestable can. The carrier may hold cans on both side via an opening between the two cans.

A container transport apparatus may comprise a substantially sturdy material suitable for carrying cans, or the like, such as cardboard, paperboard, fiberboard, or thick paper/recyclable material adapted to hold the weight of multiple cans. In the embodiments shown, the container transport apparatus may hold a plurality of stackable cans. For example, FIG. 20 depicts a container transport apparatus 2000 adapted to transport twelve (12) cans in total, with six (6) cans on each side of a support surface 2002. The term “can” as used herein may generally refer to an example of a stackable and/or nestable beverage container in accordance with embodiments of the present disclosure and may include containers that are not cans. It is contemplated that other stackable and/or nestable containers may be transported by container transport apparatus in accordance with embodiments of the present disclosure. For example, stackable bottles, or the like, may be transported via implementations of a container transport apparatus in accordance with exemplary embodiments of the present disclosure.

In accordance with exemplary embodiments of the present disclosure, beverage containers may be disposed on both sides of a support surface having apertures disposed therein. In some implementations, the support surface may be a flat or substantially flat board. For example, the support surface may be a flat piece of cardboard having apertures sized to accept at least the top portion of stackable and/or nestable cans. In some implementations, stackable cans may be held via the support surface, or the like, by a force driving the cans together by attaching the top of one can to the bottom of another can through the aperture in the support surface, thereby pulling the cans toward each other and compressing the support surface. The cans may be held onto the board because they are secured to the board and one another in accordance with embodiments of the present disclosure. For example, the cans or beverage containers may be screwed into each other or otherwise attached, and they may be held to the support surface by that attachment.

In some embodiments, stackable and/or nestable cans or beverage containers are attached to the support surface, or the like, by pinching or compressing a portion of the support surface between the cans when the cans are attached to each other. When attaching the cans together, the attachment pulls the cans inwardly toward each other and toward the support surface, such that the support surface is pinched, wedged, compressed, and/or the like between the cans. The pressure of the attachment on both sides of the board caused by the attachment of the cans to each other secures each can snugly against the board, or the like. The cans may not be attached to the board in the way that typical plastic ring packaging is used on cans, namely the plastic six pack rings secured around an upper lip of the cans. Rather, the cans secure to each other on opposing sides of a support surface, or the like, and are attached to the support surface because they are secured to each other and exert pressure on the support surface due to that connection.

It is contemplated that other numbers of holes or apertures may be used. For example, 1-15 holes may be used on the board, or the like. In a one-hole version of the transport apparatus, two (2) cans may be transported, one on each side of the support surface. In a three-hole version, up to six (6) cans may be supported and transported, three (3) cans on each side of the support surface. The transport apparatus may include holes or apertures for the nestable beverage containers and one additional aperture that may be used to form a handle to allow the user to carry the container transport apparatus, or the like.

Referring now to FIG. 20, a side view of a container transport apparatus 2000 in accordance with embodiments of the present disclosure is shown. In this exemplary implementation, the container transport apparatus 2000 comprises a support surface 2002, one or more apertures 2006, one or more rims 2004 defining the one or more apertures 2006, a handle 2010, and/or the like. Although the handle 2010 is depicted on a longer side of the implementation shown in FIG. 20, it is contemplated that the handle may be moved to any suitable location or side that allows for transport of nestable beverage cans in accordance with embodiments of the present disclosure. For example, the handle 2010 may be disposed on a shorter side, the right or left side, or on the top or bottom side. It is contemplated that more than one handle may be included, for example, one on a top side and one on a right side. In accordance with exemplary embodiments, a support surface 2002 may be adapted to carry nestable and/or stackable beverage containers. The support surface may be flat and may be made of a sturdy material for supporting the weight of stackable and/or nestable beverage cans, or the like.

In use, two or more nestable beverage cans may be joined end-to-end through the aperture, such that one can is on a first side of the support surface 2002 and another can is on the opposite side. The cans may be connected through the aperture 2006 and secured to the rim 2004 with the force of attaching the cans together. For example, using the methods described herein, the bottom of a fist can may be disposed on the support surface 2002 on a first side. The top of a second can may be disposed through the aperture 2006 on the support surface 2002 on a second side, opposite the fist side. The bottom of the first can may be joined to the top of the second can, which may be disposed through the aperture 2006. The force created by securing the cans to each other compresses upon the rim 2004 and/or the surrounding area of the support surface 2002 around the aperture 2006, such that both cans pull each other inwardly toward the support surface 2002. This inward force secures the cans to the container transport 2000.

FIG. 21 depicts a top view of a container transport 2000 with nestable beverage containers 2020, 2030 in accordance with embodiments of the present disclosure. A container transport 2000 allows beverage containers 2020, 2030 to be secured to each other through the support surface 2002 via an aperture 2006, thereby securing the containers 2020, 2030 to the support surface 2002 by the inward force created by connecting the containers 2020, 2030 to each other. The inward force secures the containers 2020, 2030 to the support surface 2002 by compressing a portion of the support surface 2002 between the attached containers 2020, 2030. In the implementation shown in FIG. 21, the support surface 2002 supports a first container 2020 and a second container 2030, or the like. It is contemplated that the container transport 2000 may be adapted to support additional or less containers than depicted.

The first container 2022 may be have a top portion 2022 and bottom portion 2024. The second container 2030 may have a top portion 2034 and a bottom portion 2032. The bottom portion of 2024 of the first container 2022 may be attached to the top portion 2034 of the second container 2032, thereby securing the containers 2020, 2032 to the support surface 2002 in a stackable and/or nestable configuration in accordance with embodiments of the present disclosure. The top portion 2034 of the second container 2030 may be disposed through an aperture 2006 though the support surface 2002 when attached to the bottom portion 2024 of the first container 2020. Greater detail of an example attachment of two stackable and/or nestable containers is shown in FIGS. 33-38. The container transport 2000 may comprise a handle 2010 adapted for lifting the transport 2000 and carrying the transport 2000 and attached beverage containers 2022, 2030. For clarity and to reduce repetition, only one set of containers 2020, 2030 are labeled in FIG. 21, although three (3) sets of containers are depicted. It is contemplated that the additional unlabeled containers may be identical to the set of labeled containers. In some embodiments, the transport 2000 may be used to support different types of containers. For example, the transport 2000 may support two different types or sizes of containers through different apertures. In these embodiments, the apertures may be of different sizes to allow for different sized containers or different types of containers.

Referring now to FIG. 22, a side view of a container transport 2200 with nestable and/or stackable containers 2220, 2230 and a stand 2237 in accordance with embodiments of the present disclosure is shown. In this implementation, a stand 2237 is presented at the bottom of the support surface 2202 and the containers 2220, 2232 are attached to the support surface 2202. A first container 2220 may include a bottom portion 2224 that is attachable to a top portion 2234 of a second container 2230. When attached, the containers 2220, 2230 may be attached together with the top portion 2234 of the second container 2230 extending through a central area 2240 which may be disposed at a center portion of an aperture 2206 through support surface 2202. The central area 2240 may be disposed on a plane extending through the support surface 2202 running parallel or substantially parallel with at least one outer surface (e.g., a front face or a back face) of the support surface 2202. In this implementation, a stand 2237 may be included that may include several legs 2236 and a stand support 2238 for supporting the legs 2236 and supporting the transport 2200 in an upright position. The stand support 2238 may be a piece of the same material comprising the support surface 2202 or may comprise a material such as cardboard, plastic, string, and/or the like, adapted to keep the stand support from collapsing by connecting two legs 2236 of the stand 2237 together. The legs 2236 may extend away from each other and a central area 2240, such that the downward pressure and the weight of the container transport 2200 and the containers 220, 2230 may be supported by the legs 2236 in an upside down “V” shaped configuration, or the like.

FIG. 23 depicts a side view of a container transport apparatus 2300 with a portion having a triangular shape in accordance with embodiments of the present disclosure. This implementation shows a different variation of the shape of a support surface 2302 of the transport apparatus 2300. In this embodiment up to six (6) cans or a “six pack” may be supported and transported by the container transport 2300. The container transport 2300 may be lifted via a handle 2310, or the like. The container transport apparatus 2300 may comprise apertures 2306 for accepting a portion of stackable and/or nestable containers and a rim 2304 surrounding and defining the apertures 2306, the rim 2304 adapted to support the containers when they are attached in a stackable configuration through the apertures 2036, and/or the like.

FIG. 24 depicts a side view of a container transport 2400 with a portion having a trapezoidal shape in accordance with embodiments of the present disclosure. This implementation shows an alternative shape for the support surface 2402. As in the previous example, this example is also adapted to transport up to six (6) beverage containers via apertures 2306 and surrounding rims 2304 and may be carried by a handle 2310 consistent with embodiments of the present disclosure.

FIG. 25 depicts a side view of a container transport apparatus 2500 with a portion having perforated, indented, or pre-bent portions 2508 surrounding the apertures 2506 through the support surface 2502 in accordance with embodiments of the present disclosure. In this implementation, perforated or indented portions 2508 may be included to allow for the cans to more easily connect with each other and secure to the transport apparatus 2500. The perforated, indented, or pre-bent portions 2508 may be disposed between an outer rim 2504 and the aperture 2506 of the transport apparatus 2500 in accordance with embodiments of the present disclosure. In some embodiments, the perforated, indented, or pre-bent portions 2508 may be disposed on a piece of material within the outer rim 2504 such that the material, which may be the same material as a support surface 2502, is thinner and of a smaller thickness than the material disposed outside of the outer rim 2504 or the like. In other words, the support surface 2502 may have a first thickness and material between the outer rim 2504 and the aperture 2506 may be thinner in thickness than the first thickness of the support surface 2502. In exemplary embodiments, this implementation may comprise a handle 2510 for allowing the transport apparatus 2500 to be lifted, carried, or otherwise hung, in accordance with embodiments of the present disclosure.

FIG. 26 depicts a side view of a container transport apparatus 2600 with a portion having indented rims 2512 disposed between outer rims 2604 and the apertures 2606 in accordance with embodiments of the present disclosure. The indented rims 2512 may allow stackable and/or nestable cans to be more easily and more securely attached to the support surface 2602. The indented rims 2512 may have a thinner thickness than the outer rims 2604 and the material of the support surface 2602 disposed outside of the outer rims 2604. The indented rims 2512 may be thinner than the outer rims 2604. The indented rims 2512 may extend from the outer rims 2604 and have a thinner thickness than the outer rims 2604. In accordance with exemplary embodiments, the container transport apparatus 2600 may comprise a handle 2610 for allowing the transport apparatus 2600 to be lifted, carried, or otherwise hung, in accordance with embodiments of the present disclosure.

FIG. 27 depicts a front view of a container transport apparatus 2700 system having three openings for supporting beverage containers 2720, 2730 in accordance with embodiments of the present disclosure. In the implementation depicted, six beverage containers 2720, 2730 are carried by the transport apparatus system 2700. The containers 2720, 2730 may be supported on opposing sides of a support surface 2702 in accordance with embodiments of the present disclosure. In this implementation the apertures may be disposed side-by-side in a vertical configuration. The top portion of a first can 2720 may be disposed through a cardboard, or the like, support surface 2702 and attached to a bottom portion of a second can 2730, or the like. The attachment of all cans depicted occurs in the same way.

FIG. 28 depicts a side view of a container transport apparatus 2800 having a central handle 2810 for supporting beverage containers 2820, 2830 in a direction substantially parallel to the handle 2810 in accordance with embodiments of the present disclosure. In this implementation, a support surface 2802 is adapted to be carried in a manner parallel to the ground, or the like. The cans 2820, 2830 are carried in an upright or vertical position in this implementation. A handle 2810 may be disposed in a center portion of the surface 2802 to allow for the support surface 2802 to be carried in a manner parallel to the ground surface, or the like. FIG. 29 depicts a top view of the container transport apparatus 2800 having a central handle 2810 for supporting beverage containers in accordance with embodiments of the present disclosure. A number of apertures 2806 may be disposed around the central handle 2810 and through the support surface 2802 for supporting cans attached in a stackable and/or nestable configuration in accordance with embodiments of the present disclosure.

FIG. 30 depicts a view of a container transport apparatus 3000 in a flattened configuration prior to assembly in accordance with embodiments of the present disclosure. The transport apparatus 3000 may be stored in this flattened position to save storage space and allow the transport apparatus 3000 to be stackable prior to assembly, like the way pizza boxes and cardboard boxes are stored prior to assembly. In accordance with exemplary embodiments, to assemble the transport apparatus 3000 and move it from a flattened storage configuration to a usable configuration for carrying nestable and/or stackable containers, a top portion or flap 3003 and a bottom portion or flap 3005 of the apparatus 3000 may be folded inwardly toward the center of a support surface 3002 in the direction indicated by arrows x and y, in some embodiments about a perforated, pre-folded, or indented fold line 3007. The transport apparatus 3000 may comprise an outer set of apertures a, b, c, d, e, and f that, when the top flap 3003 and bottom flap 3005 are folded about the fold line 3007 and moved into a usable configuration, the outer set of apertures a, b, c, d, e, and f are aligned with an inner set of apertures aa, bb, cc, dd, ee, and ff, respectively. In some embodiments, handle portions 3010, 3014 may be fed through central apertures 3012, 3016, respectively, when the top and bottom of the transport apparatus 3000 are folded in the direction indicated by arrows x and y. Handle portions 3010, 3014 may include apertures 3011, 3015, respectively, sized and shaped to allow a user to grasp the handles 3010, 3014 and carry the transport apparatus 3000.

FIG. 31 depicts a front view of the container transport apparatus 3000 shown in FIG. 30 in a folded and useable configuration in accordance with embodiments of the present disclosure. The reference indicators of FIG. 31 are the same as reference indicators of FIG. 30 and the indicated elements have the same description. In use, a user may place their hand through the apertures 3011, 3015 and lift the transport apparatus 3000 and any containers carried by the transport apparatus 3000. The containers may be attached as described above in the previous figures, through aperture pairs, such as apertures aa, a and apertures dd, d, and the like. The handle portions 3010, 3014 may be fed through be central apertures 3012, 3016, respectively. The completed handle comprising the handle portions 3010, 3014 may allow a user to pick up and transport the transport apparatus and any containers connected via the aperture pairs, and/or the like.

FIG. 32 depicts a view of a container transport apparatus 3200 in a flattened configuration in accordance with embodiments of the present disclosure. In this flattened configuration the transport apparatus 3200 may be more easily stored before it is needed for use. In this flattened configuration, an upper portion 3210 and a lower portion 3214 of the apparatus 3200 may be folded inwardly toward the center of the support surface 3202 in the direction of arrows w and z. When the upper and lower portions 3210, 3214 are folded inwardly, the apertures g, h, i, j, k, and l, align with the apertures gg, hh, ii, jj, kk, and ll, respectively. Pre-folded, perforated, indented, and/or the like fold-lines 3207 may be included on the transport apparatus 3200 for allow for easier folding of the upper portion 3210 and the lower portion 3214. When folded, handle apertures 3211, 3214 may meet in the center and upper portion 3210 and the lower portion 3214 meet in a center portion of the support surface, such that the apertures 3210, 3214 are adjacent and a user may grab the handle through both apertures 3210, 3214.

FIG. 33 depicts a front view of the container transport apparatus 3200 shown in FIG. 32 in a folded and useable configuration in accordance with embodiments of the present disclosure. The reference indicators of FIG. 33 are the same as reference indicators of FIG. 32 and the indicated elements have the same description. Aperture pairs g, gg and j, jj, and/or the like may be aligned when the apparatus 3200 is folded into a useable position, allowing containers to be attached via the aperture pairs and transported in accordance with embodiments of the present disclosure. The upper portion 3210 and the lower portion 3214 may meet in a central location such that they are adjacent to each other and may be used to form a handle for the transport apparatus 3200. In this embodiment, the containers may be transported via one or more aperture pairs and the support surface in a vertical configuration, wherein a horizontal plane through the bottom surface of the containers is parallel or substantially parallel to the ground area under the transport apparatus 3200.

FIG. 34 depicts a front view of a container transport apparatus 3400 and beverage containers 3402, 3404 in accordance with embodiments of the present disclosure. In accordance with exemplary embodiments, a first beverage container 3402 may be attachable to a second beverage container 3404 via the methods described hereinabove, or the like. A first beverage container 3402 may comprise a bottom portion 3406. The bottom portion 3406 may include a base of the container 3402 and a lower attachment portion 3408 for attaching to a portion of a second beverage container 3404, or the like. The attachment portion 3408 may comprise threads, tab inserts, or other suitable attachment members and methods consistent with the present disclosure. A second beverage container 3404 may comprise a top rim 3410 and an upper portion 3414. The second beverage container 3404 may comprise a connecting portion 3412 disposed between the upper rim 3410 and the upper portion 3414 on the outer surface of the container 3404. The connecting portion 3412 may be angled, sloped, tapered, or the like, wherein the upper rim 3410 has a smaller circumference than the upper portion 3414, or the like. The upper portion 3414 may be wider than the upper rim 3410 such that when the can is inserted through an aperture 3420 through a support surface 3418, the upper rim 3410 may fit through the aperture 3420 but the upper portion 3414 may not fit through the same aperture 3420, due to its wider size and larger circumference.

In some embodiments, the second beverage container 3404 may comprise an upper attachment portion 3416 including, for example, threading or bent tabs designed and formed to couple and attach to the bottom portion 3406 of the first beverage container 3402, via a lower attachment portion 3408 consistent with stackable and/or nestable cans described herein, or the like. The dotted lines are included to indicate the path of connection between the beverage containers 3402, 3404 through an aperture 3420 in the supporting surface 3418 of the transport apparatus 3400, or the like. When attached, the containers 3402, 3404, which may be cans, pull inwardly toward the support surface 3418, wherein the containers 3402, 3404 pinch in and/or compress the support surface 3418, thereby securing the containers 3402, 3404 to the support surface 3418 so they may be carried by a transport apparatus consistent with the present disclosure.

FIG. 35 depicts a front view of a container transport apparatus 3400 and beverage containers 3402, 3404 in accordance with embodiments of the present disclosure. In this figure, the top rim 3410 of the second beverage container 3404 is inserted through the aperture 3420 such that the rim 3410 of the second beverage container 3404 is disposed through the supporting surface 3418 and the connecting portion 3412 is adjacent to the supporting surface 3418. The bottom portion 3406 of the first can 3402 may then be attached to the second can 3404 via the lower attachment portion 3408 and the upper attachment portion 3416, and/or the like.

FIG. 36 depicts a front view of a container transport apparatus 3400 and beverage containers 3402, 3404 in accordance with embodiments of the present disclosure. In this figure, the beverage containers 3402, 3404 are coupled with each other in accordance with exemplary embodiments of the present disclosure. The bottom portion 3406 of the first container 3402 may be attached in a nestable and/or stackable configuration to the second container 3404 via the aperture 3420, such that the top rim of the second container 3404 is disposed within or nested within the bottom portion 3406 of the first container 3402, thereby attaching both containers 3402, 3404 together. When both containers 3402, 3404 are connected together through the aperture 3420 in the support surface 3418 the bottom portion 3406 of the first container 3402 and the connecting portion 3412 of the second container 3404 are disposed adjacent to the support surface 3418 and press inwardly toward and against the support surface 3418, thereby applying pressure thereto and securing both containers 3402, 3404 to the support surface 3418 for transport by a transport apparatus in accordance with exemplary embodiments of the present disclosure.

FIG. 37 depicts a perspective left side view of container transport apparatus 3400 and beverage containers 3402, 3404 connected thorough the support surface 3418 such that the bottom portion 3406 of the first can 3402 is pressed against the support surface 3418 in accordance with embodiments of the present disclosure. In this figure, the beverage containers 3402, 3404 are coupled with each other in a stackable and/or nestable configuration in accordance with exemplary embodiments of the present disclosure. FIG. 38 depicts a perspective right side view of a container transport apparatus 3400 and beverage containers 3402, 3404 in accordance with embodiments of the present disclosure. In this figure, the beverage containers 3402, 3404 are coupled with each other through an aperture 3420 in the support surface 3418 in accordance with exemplary embodiments of the present disclosure. In this view the connecting portion 3412 of the second container 3404 is pressed against the support surface 3418 in accordance with embodiments of the present disclosure. In this figure, the beverage containers 3402, 3404 are coupled with each other in a stackable and/or nestable configuration in accordance with exemplary embodiments of the present disclosure.

While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the invention may be devised without departing from the basic scope thereof. For example, although numerous embodiments having various features have been described herein, combinations of such various features in other combinations not discussed herein are contemplated within the scope of embodiments of the present disclosure. 

What is claimed is:
 1. A container transport system, the system comprising: a container transport apparatus comprising: a support surface for supporting one or more stackable beverage containers; at least one aperture sized to accept a portion of one or more stackable beverage containers; and a handle for transporting the container transport apparatus system; and at least two stackable beverage containers attached to the container transport apparatus via at least one aperture.
 2. The system of claim 1, wherein the handle is integral with the support surface.
 3. The system of claim 1, wherein the handle extends outwardly from support surface.
 4. The system of claim 1, wherein the support surface comprises at least one of fiberboard, cardboard, wood, or metal.
 5. The system of claim 1, wherein the stackable beverage containers comprise: a substantially cylindrical voluminous body being defined by a top portion, a bottom portion and a sidewall, the top portion comprising a single opening into a voluminous body; an upper attachment portion for attaching to a lower attachment portion of an adjacent stackable beverage container; and a lower attachment portion for attaching to an upper attachment portion of an adjacent stackable beverage container.
 6. The system of claim 1, wherein the stackable beverage containers are cans.
 7. The system of claim 1, wherein each of the cans are disposed on opposite sides of the support surface and connected to each other through the at least one aperture.
 8. The system of claim 1, wherein the handle is adapted to hold the weight of the transport apparatus and the stackable beverage containers.
 9. A container transport apparatus comprising: a support surface for supporting one or more stackable beverage containers; at least one aperture sized to accept a portion of one or more stackable beverage containers; and a handle for transporting the container transport apparatus system.
 10. The apparatus of claim 9, wherein the handle is integral with the support surface.
 11. The apparatus of claim 9, wherein the handle extends outwardly from support surface.
 12. The apparatus of claim 9, wherein the support surface comprises at least one of fiberboard, cardboard, wood, or metal. 